Apparatus for inserting a flexible preform in a mold

ABSTRACT

A method for inserting a flexible, oversized preform into an opening in a hollow mold is disclosed. The oversized preform is initially formed so as to have a configuration similar to that of the interior surfaces of the mold. The cross sectional size of the preform relative to the mold is temporarily reduced by forming an inwardly projecting furrow in the preform so that the preform may be inserted into the mold. An assembly for inserting the preform into the mold and reducing the cross sectional size of the preform as it is inserted into the mold is also disclosed.

United States Patent Wiltshire APPARATUS FOR INSERTING A FLEXIBLE PREFORM IN A MOLD Arthur'- J. Wiltshire, 352 Dumbarton Blvd., Cleveland, Ohio 44124 Filed: Apr. 6, 1972 Appl. No.: 241,707

lnventor:

US. Cl 425/392, 29/235, 29/451 Int. Cl B28b 11/08 Field of Search 425/383, 392, 110;

References Cited UNITED STATES PATENTS 7/1969 Harding 29/235 2/1947 Pityo 425/392 X 3/1925 McMillin et al. 425/392 3,673,673 7/1972 Wiltshire 29/451 Primary ExaminerI-l. A. Kilby, Jr. Att0rneyl-larold F. McNenny et al.

[57] ABSTRACT A method for inserting a flexible, oversized preform into an opening in a hollow mold is disclosed. The oversized preform is initially formed so as to have a configuration similar to that of the interior surfaces of the mold. The cross sectional size of the preform relative to the mold is temporarily reduced by forming an inwardly projecting furrow in the preform so that the preform may be inserted into the mold. An assembly for inserting the preform into the mold and reducing the cross sectional size of the preform as it is inserted into the mold is also disclosed.

8 Claims, 3 Drawing Figures APPARATUS FOR INSERTING A FLEXIBLE PREFORM IN A MOLD BACKGROUND OF THE INVENTION This invention relates generally to the molding of fiber-reinforced, plastic articles, such as tanks or the like, wherein a fiber preform is subsequently impregnated with plastic material. More particularly, a novel and improved method and assembly for inserting a flexible, oversized preform into a mold are disclosed.

Although this invention is concerned with the molding of fiber-reinforced plastic articles generally, it will be discussed herein with particular reference to the molding of fiberreinforced plastic tanks.

PRIOR ART In the molding of fiber-reinforced, plastic articles such as tanks, one commonly used method includes initially forming a hollowpreform. In thecase of fiberreinforced, cylindrical tanks, the preform includes a tubular sidewall portion having an integrally formed end wall at one end. The preform consists of a wall formed by a multitude of short lengths of fibers randomly oriented in the wall and bonded by a settable resin which holds the fibers together but which does not fill the voids between the fibers.

One method of forming a preform which is particularly suited-to commercial production involves the step of providing a perforated form which is rotated about its longitudinal axis while a vacuum is applied internally. A fiber chopper cuts a continuous strand of fiberreinforcing material, such as a glass fiber filament, into short lengths and directs the c'hoppedfibers toward the rotating form. The vacuum applied to the perforated form causesthe fibers to be laid up on the form in a random manner. A settable binder resin is sprayed onto the fibers as they are deposited on theform. The vacuum applied to the perforated form, the amount of resin spray. and the amount of fibers deposited on the form may be controlled so that the preform is formed initially to have a configuration generally similar to the interior cavity of the mold.

After the binder is cured, the preform is removed from the form and is then inserted into the mold and compressed against the inner surfaces of the mold by expandingan inflatable bag within the preform. A settable resin is then caused to flow through the preform and the resin is subsequently cured. A more detailed description of the preform fabrication technique is generally set forth in the copending application of Arthur J. Wiltshire et al., Ser. No. 742,692, filed July 5, 1968.

When fiber-reinforced plastic articles are fabricated in this manner, the preform must be formedso as to satisfy rigorous dimension requirements. In particular, the exterior dimensions of the preform must be substantially equal to the interior dimensions of the mold and lie within a narrow tolerance range.

If the preform is oversized, it cannot be inserted into the mold and must be discarded. There is no economical way to reshape the preform, nor is there a method of salvaging the materials forming the preform. Consequently, valuable production time and materials are lost.

If the preform s exterior dimensions are substantially equal to the interior dimensions of the mold, the preform may be carefully inserted into the mold. Since the exterior surface of the preform may be disrupted or torn during the inserting process, an experienced assemblyman is required to carefully position the preform in the mold. Consequently, in this instance, the preform inserting process is slow and requires a skilled assemblymans services. In addition, there still exists the possibility that the preform may be torn during the process so as to render it unusable.

The difficulties encountered in forming a preform with exterior dimensions substantially equal to the interior dimensions of the interior of the mold may be fully appreciated when considered in view of the preform fabrication technique described above. As there noted, the preform is formed by depositing fibers on a rotating form and spraying the deposited fibers with a resin binder. Consequently, the exterior preform dimensions are a function of several independent variables none of which readily lend themselves to precise dimensional control. This is especially critical in view of the fact that a typical mold having an 8.275 inch diameter has a tolerance of 0.+0.005 inch.

Although it is desirable to form the preform with exterior dimensions substantially equal to the interior dimensions of the mold so as to provide a minimum of clearance, several additional fabrication problems arise if the preform is undersized. For example, if the preform is in fact too small, it may split when the inflatable bag is inserted into the preform and expanded so as to compress the preform against the inner surfaces of the mold. Consequently, the final product will not be fiberreinforced in the area of the split and a weak point may exist in the structure so as to render the product unusable. In addition, if the preform is undersized but does not split when subjected to internal bag pressure, a second structural defect may arise which will also render the final product useless. In this instance, the undersized preform fails to uniformly contact the inner surfaces of the mold when bag pressure is applied and resin-rich localized areas at the exterior surface of the final product result. The resin-rich areas will not be adequately fiber-reinforced, and the final product may have a tendency to crack in these areas.

Consequently, according to the methods of the prior art, it was considered necessary that the exterior dimensions of the preform be substantially equal to the interior dimensions of the mold and be within a narrow tolerance range. However, the maintenance of this narrow tolerance range is extremely difficult in view of the preform fabrication technique and the nebulous value of the maximum amount of acceptable clearance.

SUMMARY OF THE lNVENTlON The present invention provides a method and an assembly for inserting a flexible, oversized preform in a hollow mold. According to the present invention, the cross sectional size of the preform is temporarily reduced so that it may be easily inserted into the mold. This reduction in the cross sectional size of the preform is provided by forming an inwardly projecting furrow in the preform to reduce the cross sectional size of the preform by gathering portions of the preform into the furrow.

The present invention also provides an assembly for inserting the flexible, oversized preform into the mold. The assemblyincludes an inserting mandrel which has exterior dimensions less than the interior dimensions of the mold and the hollow preform so that the mandrel may fit within the preform. According to the preferred embodiment of the present invention, the mandrel provides an aperture extending along its outer peripheral surface. The assembly also includes a paddle dimensioned to coact in sliding relationship with the aperture of the inserting mandrel. The paddle provides a surface which projects towards the aperture. The paddle is positioned adjacent to the open end of the hollow mold and along the interior surface of the mold. The preform is positioned over the inserting mandrel and inserted into the mold so that the aperture of the inserting mandrel and the paddle are aligned. The preform will lie intermediate the aperture of the mandrel and the paddle, which coact so as to form an inwardly extending furrow in the preform as it is inserted into the mold. In this manner, the cross sectional size of the preform is temporarily reduced so that it will fit into the mold. The inserting mandrel and the paddle may then be withdrawn from the mold. An inflatable bag is then inserted within the preform and inflated so as to force the preform against the interior surface of the mold. The subsequent molding operations as described above may then be preformed.

The method of the present invention eliminates the problems existing in the prior art which are indicated above. Initially, it may be noted that the tolerance range with respect to preform size is substantially increased. This is true since the upper limit of the tolerance range is no longer limited or fixed by the interior size of the mold. Consequently, many of the preforms which were formerly rejected as being oversized may be used to form satisfactory end products.

Since the upper limit of the tolerance size range of preforms has been increased by the method of the present invention, the preforms may be consistently made within the upper portions of this tolerance range. Therefore, the problems associated with undersized preforms are substantially eliminated.

It may also be noted that when the preform inserting assembly of the present invention is employed, the preform may be quickly and accurately positioned inside the mold. As a result, the preform inserting process will entail a minimum of production time and will not require the services of a skilled assemblyman.

Other advantages of this invention will become apparent from the following detailed description and the accompanying drawings.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a perspective view of an inserting mandrel and a paddle according to the present invention;

FIG. 2 is a composite sectional side view of the assembly shown in FIG. 1, a mold, and a preform; and

FIG. 3 is a sectional view, the plane of the section being indicated by the line 33 in FIG. 2.

DETAILED DESCRIPTION OF THE DRAWINGS FIG. 1 illustrates the preferred embodiment of an assembly which is useful in inserting an oversized preform into a hollow mold. This assembly is particularly adapted for the manufacture of tanks of the type often used for water softeners or the like. The illustrated assembly includes a hollow inserting mandrel l and a paddle 12. The inserting mandrel includes a cylindrical portion 14 extending to a rearward open end 16 and a foward end 18. The forward end 18 is substantially dome-shaped'and closed having an exterior radial dimension which may be greater than that of the cylindrical portion l4.

The inserting mandrel 10 is substantially hollow and provides an aperture 20 extending into the hollow interior of the mandrel. The aperture 20 extends axially along the cylindrical portion 14 from the forward face 18 to the rearward face 16. Adjacent to the periphery of the aperture 20 along the cylindrical portion 14 there are mandrel support guides 22 and 24 which project radially outward. The mandrel support guides provide the cylindrical portion 14 with a radial dimension at the plane of the aperture 20 substantially equal to the exterior radial dimension of the forward end 18. Therefore, the aperture 20 is defined by the coplanar edges 22a and 24a of the mandrel support guides 22 and 24 along the cylindrical portion 14 of the inserting mandrel and the forward edge of the aperture is defined by the edge 26 of the forward end face 18. It should be noted that the aperture 20 may be formed merely by a relieved portion in the exterior peripheral surface of the cylindrical portion 14 and the forward end 18 may have peripheral dimensions similar to those of the aperture 20.

The paddle 12 is provided with peripheral dimensions that substantially mate with the aperture 20. In the embodiment illustrated in FIG. 1, the paddle 12 has a substantially rectangular shape and provides an arcuate projecting surface 28. The projecting surface 28 extends towards the aperture 20 when the paddle and the inserting mandrel are employed in accordance with the method of this invention. The paddle 12 may have an axial length which is equal to about one-half to about three-fourths of the axial length of the aperture 20.

FIG. 2 illustrates a hollow preform 30 positioned in a mold 32 by the assembly shown in FIG. 1. The mold 32 has a cylindrical portion 34 extending to an open rearward end 38 and a closed forward end 36. The preform 30 has a similar configuration and is comprised of a cylindrical portion 33 extending to a closed forward end 31 and an open rearward end 35.

In the method of the present invention, the preform 30 is initially positioned over the inserting mandrel 10 since the inserting mandrel has exterior dimensions less than the interior dimensions of the preform. The paddle I2 is positioned inside the mold 32 adjacent to the open end 38. To this end, the paddle 12 is provided with a handle 40 which is formed to clip over the open end 38 of the mold so as to securely position the paddle.

The inserting mandrel 10, with the preform 30 positioned over it, is then inserted into the mold. A handle 42 is provided across the open end 16 of the inserting mandrel to facilitate this step. As the preform is being inserted into the mold, the aperture 20 and the paddle 12 are appropriately aligned so as to coact in sliding relationship. As the preform 30, which lies intermediate the inserting mandrel l0 and the paddle 12, is inserted into the mold, the aperture 20 and the projecting surface 28 form an inwardly extending furrow 44 in the preform. As shown in FIG. 2, the preform 30 has been completely inserted into the mold and the furrow 44 has been formed in the preform. The furrow axially extends along substantially the entire axial length of the cylindrical portion 33 of the preform 30.

As best shown in FIG. 3, the furrow 44 reduces the cross sectional size of the preform 30 by gathering portions of the preform material. To effect this gathering '5 of preform material, the inserting mandrel l and the paddle 12 provide an increased circumferential path about which the preform must travel and a localized area where the excess preform material is accumulated.

Once the preform 30 has been properly positioned in the mold 32, the inserting mandrel may be withdrawn from the mold by means of the handle 42.

Oncetheinserting mandrel and the paddle have been removed from the mold, the inflatable bag may be inserte'd into the preform and inflated so as to compress the preform against the inner surfaces of the mold. The furrow-44 which was formed in the preform will also be compressed and the portions of the preform formerly gathered in the furrow will be uniformly distributed throughout the preform. Consequently, the preform will be compressed uniformly against the inner surfaces of the mold and the subsequent molding steps, described above, may be preformed.

When the method of the present invention is employed as described above, the preform does not have to be initiallyformed so as to satisfy the rigorous dimensional requirements. imposed by the prior art techniques. in particular, the maximum interior mold dimensions do not limit the exterior dimensions of the preform and an oversized preform is no longer discarded as unusable. For example, when the method of thepresent invention is employed, a preform having an outside diameter:0.020 inch greater than the inside diameter of the moldis easily inserted into the mold and is usable. In effect, the upper limit of the narrow tolerance range of theprior art methods has been increased.

Since the exterior dimensions of the preform do not have to be substantiallyequal to the interior dimensions of the mold when the method of the present invention is employed, an experienced assemblyman is no longer required to carefully insert the preform into the mold without tearing or disrupting the exterior surface of thepreform. In fact, when the method and assembly of the present invention are utilized, an inexperienced assemblyman is able to quickly and correctly insert the preform into the mold. Since the assembly of the present invention fits the preform to the mold as it is being inserted, production time is not wasted in a tedious fitting process.

The prior art problems with respect to the degree which the preform could be undersized or the amount of acceptable clearance between the preform and the mold are also eliminated by the method of the present invention. Since the method of the present invention utilizes oversized preforms, there is no need to provide a clearance between the preform and the mold and the problems of the prior art are substantially avoided. In particular, the preform will not tend to split as the in flatable bag compresses it against the inner surfaces of the mold, since the exterior dimensions of the preform are actually greater than the interior dimensions of the mold. In addition, the final product will not tend to have resin-rich areas at its exterior surface, since sufficient fiber-reinforcing materials are provided by the oversized preform.

The assembly of the present invention also radially aligns the preform within the mold as it is inserted. The mandrel support guides 22 and 24 provide the cylindrical portion 14 of the inserting mandrel 10 with a radial dimension equal to that of the expanded forward end 18. Thus, the support guides 22 and 24 and the forward end 18 provide a coplanar support surface for the inserting mandrel. The support guides and the forward end may be appropriately dimensioned so as to radially align the mandrel and the preform within the mold. This feature of the present invention is best illustrated in FIG. 3.

In addition, the end face 18 of the inserting mandrel is provided with apertures 46, 48, and 50 which permit the free passage of air. These apertures permit air to es cape from the mold, through the preform lying intermediate the mold and the forward end, as the preform is inserted, and prevent the formation of a vacuum as the inserting mandrel is withdrawn from the preform.

Although a preferred embodiment of this invention is illustrated, it is to be understood that various modifications and rearrangements of parts may be resorted to without departing from the scope of the invention.

What is claimed is:

1. An assembly for inserting a hollow, flexible, oversized preform into an opening in a hollow mold to lay up the preform against the inner surface of the mold, said preform substantially corresponding to the inner mold surface, comprising inserting mandrel means having exterior dimensions less than the interior dimensions of said mold and said hollow preform so that said mandrel may fit within said preform, said inserting mandrel means including a substantially cylindrical hollow portion extending to a rearward open end and a rounded forward end suitable for positioning said preform means in molding relationship with the interior of said mold, a paddle means which includes means for positioning said paddle means along said inner molding surface, said inserting mandrel means having a relieved portion extending inwardly along its outer peripheral surface, said paddle means having a portion dimensioned to coact with said relieved portion and provide a surface projecting toward said relieved portion, said paddle portion having a lateral dimension substantially corresponding to the lateral dimensions of said relieved portion, said preform being positioned around said mandrel means, said paddle means being aligned with said relieved portion between the exterior surface of said preform and the interior surface of said mold, said paddle means coacting with said relieved portion to provide a furrow in said preform and temporarily reduce the cross sectional size of the said preform member relative to the corresponding cross sectional size of the inner mold surface.

2. An assembly as set forth in claim 1, wherein said mandrel includes support guide means extending radially outward from the edges of said relieved portion to said inner dimension of the preform.

3. An assembly as set forth in claim 2, wherein said forward end includes at least one aperture therethrough.

4. An assembly as set forth in claim 3, wherein said inserting mandrel means includes a substantially domeshaped forward end having an outside circumferential dimension greater than that of said cylindrical portion and said radial support guides extending substantially equal to said greater dimension.

5. An assembly as set forth in claim 4, wherein said relieved portion axially extends along the peripheral surface of said inserting mandrel means substantially from said forward end toward said rearward end.

6. An assembly as set forth in claim 5, wherein said relieved portion is an aperture extending into the interior of said hollow inserting mandrel.

one-half to about three-fourths of the axial length of said aperture and a width less than that of said aperture. 

1. An assembly for inserting a hollow, flexible, oversized preform into an opening in a hollow mold to lay up the preform against the inner surface of the mold, said preform substantially corresponding to the inner mold surface, comprising inserting mandrel means having exterior dimensions less than the interior dimensions of said mold and said hollow preform so that said mandrel may fit within said preform, said inserting mandrel means including a substantially cylindrical hollow portion extending to a rearward open end and a rounded forward end suitable for positioning said preform means in molding relationship with the interior of said mold, a paddle means which includes means for positioning said paddle means along said inner molding surface, said inserting mandrel means having a relieved portion extending inwardly along its outer peripheral surface, said paddle means having a portion dimenSioned to coact with said relieved portion and provide a surface projecting toward said relieved portion, said paddle portion having a lateral dimension substantially corresponding to the lateral dimensions of said relieved portion, said preform being positioned around said mandrel means, said paddle means being aligned with said relieved portion between the exterior surface of said preform and the interior surface of said mold, said paddle means coacting with said relieved portion to provide a furrow in said preform and temporarily reduce the cross sectional size of the said preform member relative to the corresponding cross sectional size of the inner mold surface.
 2. An assembly as set forth in claim 1, wherein said mandrel includes support guide means extending radially outward from the edges of said relieved portion to said inner dimension of the preform.
 3. An assembly as set forth in claim 2, wherein said forward end includes at least one aperture therethrough.
 4. An assembly as set forth in claim 3, wherein said inserting mandrel means includes a substantially dome-shaped forward end having an outside circumferential dimension greater than that of said cylindrical portion and said radial support guides extending substantially equal to said greater dimension.
 5. An assembly as set forth in claim 4, wherein said relieved portion axially extends along the peripheral surface of said inserting mandrel means substantially from said forward end toward said rearward end.
 6. An assembly as set forth in claim 5, wherein said relieved portion is an aperture extending into the interior of said hollow inserting mandrel.
 7. An apparatus as set forth in claim 6, wherein said paddle means includes a rectangle having an arcuate projecting surface.
 8. An apparatus as set forth in claim 7, wherein said paddle means has an axial length equal to from about one-half to about three-fourths of the axial length of said aperture and a width less than that of said aperture. 